Image data recording system including memory card

ABSTRACT

An electronic video data recording system includes a camera apparatus for photoelectric-converting an incident optical image into electronic image data: a memory card detachably mounted on the camera apparatus and containing a random access memory to store the electronic image data; and a video tape recorder or other outside storage device for recording the image data which have been previously stored in the random access memory of the detachable memory card, the image data being supplied from the memory card through the camera apparatus. When taking the image, the detachable memory card is mounted on the camera apparatus so as to store the image data into the random access memory thereof. When the image data stored in the detachable memory card are recorded, they are transferred from the memory card into the video tape recorder, via the camera apparatus. The detachable memory card can then be re-used.

This application is a Continuation of application Ser. No. 07/957,999, filed Oct. 8, 1992 now abandoned, which is Division of Ser. No. 07/835,105 Filed Feb. 12, 1992 now U.S. Pat. No. 5,200,863, which is a Continuation of Ser No. 07/503,113 filed Mar. 28, 1990. now abandoned which is a Continuation of Ser. No. 07/185,491 filed Apr. 25, 1988 (Abandoned).

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention generally relates to an image data recording system for receiving an optical image incident upon an image recording system through a lens, for converting the received optical image into electronic image data, and for storing the electronic image data therein. More specifically, the present invention is directed to an image data recording system utilizing memory cards to store the electronic image data.

2. Description of the Related Art

As an image data recording system, a so-called “electronic still camera” has been practically marketed. In the commercially available electronic still cameras, still images are optically and electrically processed to be stored in a recording medium, for instance, a magnetic disk.

More specifically, in the conventional electronic still camera, a semiconductor imaging element, e.g., a charge-coupled device (referred to as a “CCD”) is employed to optically receive a still image and convert it into a corresponding electronic image signal. After the electronic image signal is processed to have a signal format suitable for a television signal, the processed image signal is modulated into an FM (frequency modulation) image signal. Then, the FM image signal is recorded onto a magnetic disk in an analog signal form. If such an electronic still camera records the FM image signals with a field recording format, 50 still pictures or complete images can be recorded on a magnetic disk.

In such a conventional magnetic disk type electronic still camera, miniaturization of the electronic still camera meets with practical difficulties, because there is a size limitation to manufacture of a compact driving mechanism for driving the magnetic disk.

Accordingly, to solve these difficulties of the conventional magnetic disk type electronic still camera, another type of electronic still camera employing a built-in semiconductor memory (referred to as a “RAM”) has been recently developed, in which an analog still image signal is processed to obtain a digital still image signal. The digital still image signal, or digital image data is stored in the built-in semi-conductor memory (RAM).

However, the semiconductor memory type electronic still camera has another drawback. In general, when a single still image is stored into a semiconductor memory, a memory capacity of more than 2 M bits (mega bits) is required for each still image. Therefore, to store 50 still pictures (or images) in such a semiconductor memory type still camera, which is similarly performed in the magnetic disk type still camera, a semiconductor memory having a memory capacity of more than 100 M bits is required. However, a semiconductor memory type still camera having such an extremely high memory capacity is not practically available.

SUMMARY OF THE INVENTION

The present invention has been accomplished in an attempt to solve the problems mentioned above. An object of the invention is therefore to provide a still image recording system wherein a compact camera body can be realized and a relatively large quantity of still images can be temporarily or permanently stored in a detachable memory unit.

To achieve the above-described object of the invention, an image data recording system of the present invention comprises: a housing means; optical means arranged at least partly in the housing means, for forming an optical image on a predetermined plane in the housing means; image data processing means arranged in the housing means for producing digital electronic image data in response to the optical image; memory means detachably mounted to the housing means and electrically coupled to the image data processing means when mounted to the housing, means, for storing the digital electronic image data therein; output terminal means arranged in the housing means and being coupled for outputting the digital electronic image data derived from the detachable memory means when the detachable memory means is mounted to the housing means; and control means arranged in the housing means, for controlling a writing operation of the digital electronic image data into the detachable memory means when the detachable memory means is mounted to the housing means, and for controlling a reading out operation of the digital electronic image data to the output terminal means from the detachable memory means when the detachable memory means is mounted to the housing means.

According to a further feature of the invention, a peripheral memory means, arranged outside of the housing means, is detachably coupled to the output terminal means, for storing the digital electronic image data therein which was read out from the detachable memory means and which was output from the output terminal means.

A display means is preferably coupled to at least one of the output terminal means and the peripheral memory means, for displaying an image representative of the digital electronic image data which was stored in the detachable memory means.

After the digital electronic image data is read out from the detachable memory means and stored in the peripheral memory means (such as a video tape recorder), the detachable memory means can be re-used or erased and stored for later re-use.

The detachable memory means may be memory cards each containing at least one semiconductor memory chip, or other detachable memory card-like devices.

With the above-described arrangements of the still image recording systems according to the present invention, a compact and portable electronic still camera can be obtained, since a disc drive mechanism is not needed. In addition, the effective memory capacity of the system using detachable semiconductor memory units is equal to, or higher than, that of the conventional electronic still camera using RAM memory in the conventional manner or using the conventional disc drive arrangement.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 schematically shows a block diagram of an electronic still camera system according to the invention;

FIG. 2 is a perspective view of a still camera apparatus employing the electronic still camera system shown in FIG. 1;

FIG. 3 is a schematic block diagram of a circuit arrangement of the camera apparatus shown in FIG. 2:

FIG. 4 is a schematic block diagram to a circuit arrangement of the video tape recorder shown in FIG. 1:

FIGS. 5 and 6 illustrate recording formats of an image memory employed in a memory card shown in FIG. 3;

FIG. 7 is a time chart for illustrating output signal conditions of major circuit portions in the circuit arrangement shown in FIG. 3 while a signal transfer operation is performed;

FIGS. 8 to 10 show recording formats of the video tape recorder illustrated in FIG. 4; and

FIG. 11 is a schematic block diagram of another circuit arrangement for the camera apparatus shown in FIG. 2 according to a second embodiment of the invention.

DETAILED DESCRIPTION OF THEPREFERRED EMBODIMENTS OVERALL ELECTRONIC STILL CAMERA SYSTEM

In FIG. 1, there is shown an electronic still camera system utilizing an image data recording system according to the invention. The electronic still camera system includes a camera apparatus 10 which is shown in FIG. 2.

The camera apparatus 10 includes a housing 11. An optical unit 12 having lenses, a diaphragm and other optical components (not shown in detail), is mounted to a front surface portion of the housing 11. A release or shutter switch 13 is provided, for example on an upper surface of the housing 11, and an insertion opening 14 for a memory card 24 is formed for example on an upper surface of the housing 11. The memory card 24 is a detachable memory card containing an image data storage memory, and will be discussed hereinafter. On a rear surface of the housing 11, there are provided a view finder 15, an operation mode selecting switch 16, an output mode selecting switch 17 and a liquid crystal display panel 18. The output mode selecting switch 17 functions to selectively feed the output signal to a video tape recorder 25, or a monitor 27, in analog signal form, or in digital signal form when the image data stored in the memory card 24 is transferred to the video tape recorder 25, or to the monitor 27.

A signal output terminal 19 is provided on one side surface of the housing 11, for example the right side as viewed in FIG. 2. This signal output terminal 19 comprises a digital image output terminal 19a, an analog image output terminal 19b, a synchronizing (referred to as a “sync”) signal output terminal 19c, and a recorder control signal terminal 19d.

SIGNAL PROCESSING SYSTEM IN CAMERA APPARATUS

Referring now to FIG. 1, an internal signal processing system of the electronic still camera apparatus 10 will be described in detail.

A control unit 20 is provided for controlling the overall operation of the electronic still camera apparatus 10 in response to switching operations of the various switches 13. 16 and 17. An optical/photoelectric converting unit 21 is connected to the control unit 20. The optical/photoelectric converting unit 21 converts an optical image incident upon converting unit 21 through the optical unit 12 into an electrical signal and outputs the electrical signal as an electrical image signal. A signal processing unit 22 is connected to the optical/photoelectric converting unit 21 and also to the control unit 20 so as to perform a predetermined signal processing operation on the electrical image signal input from the optical/photoelectric converting unit 21. The signal processing unit 22 transfers the processed electrical image signal to the memory card 24 which is detachably connected Lo the camera apparatus 10, and transfers a television video signal to a liquid crystal television unit 23 after the image data (i.e., the processed image signal) is converted into a television video signal, and furthermore, transfers either the above-described television video signal or a digital image signal to the video tape recorder 25. The liquid crystal television unit 23 is connected to the signal processing unit 22 and to the control unit 20 in order to display on the liquid crystal display panel 18 an image representative of the television video signal sent from the signal processing unit 22. The displayed image corresponds to the optical image received by the converting unit 21.

The memory card 24, is detachably inserted into the insertion opening 14 for the memory card formed on the camera apparatus 10 such that the inserted memory card 24 is electrically connected to the above-described signal processing unit 22. The memory card 24 comprises a random access memory (RAM) having a memory capacity of 32 M bits (mega bits) by means of which four (4) still pictures imaged with the frame recording format by the camera apparatus 10 can be stored.

The above-described video tape recorder 25, when connected to the output terminal 19, magnetically records the image signals derived from the memory card 24 of the camera apparatus 10 on a magnetic cassette tape 26 for permanent or long term or short term storage of the image signals corresponding to the images.

A monitor 27 is connected to the video tape recorder 25 to display an image in response to a television video signal output from the video tape recorder 25.

CIRCUIT ARRANGEMENT OF CAMERA APPARATUS

Referring now to FIG. 3, a detailed circuit arrangement of the camera apparatus 10 will be described.

An optical processing section 30 includes lenses, a shutter and a lens driving mechanism (not shown in detail). In response to a control signal from an optical processing control section 31, the optical processing section 30 moves the lenses, and actuates the diaphragm and shutter. The optical processing control section 31 operates as follows. Focus detecting information, diaphragm-opening-angle information, and shutter-opening time information are supplied to the optical processing control section 31 from a control section 33 based upon a sensor output of a sensor 32 for optically sensing an optical image incident upon the optical processing section 30 in response to an output of a switch 13a which is closed by depressing the release (or shutter) switch over half of its travel path. In accordance with the above-described various information, the optical processing control section 31 outputs control signals to the optical processing section 30.

The optical image coming through the optical processing section 30 is focused on an image sensing device 34. The image sensing device 34 may be any of solid-state imaging elements fabricated by, for example, a CCD (charge-coupled device) image sensor or a MOS (metal-oxide-semiconductor) image sensor. Solid state image sensing device 34 comprises photoelectric converting elements (not shown) which are arranged in a two dimensional arrangement together with color filters (not shown) having predetermined patterns. Image sensing device 34 is driven by a device drive section 35 in response to a control signal issued by the control section 33.

An output signal “A” derived from the imaging device 34 is supplied to a video signal processor 36 which functions as a color separating circuit. The video signal processor or color separating circuit 36 produces a luminance signal (monochrome signal) “Y” corresponding to each pixel and each of color signals (R, G, B) based upon the photoelectric converting signal which is produced by the light information output from the image sensing device 34 via respective color filters, and also produces color difference signals (R-Y) and (B-Y) from the luminance signal “Y” and the color signals (R,G,B).

The color difference signals (R-Y), (B-Y) derived from the color separating circuit 36 are supplied to a line sequential processor 37. The line sequential processor 37 alternately selects the color difference signals (R-Y), (B-Y) supplied from the color separating circuit 36 every one pixel, and sequentially outputs the selected color difference signal. Both the luminance signal “Y_(A1)” derived from the color separating circuit 36 and the color difference signal “C_(A1)” output from the line sequential processor 37 are supplied to corresponding A/D (analog-to-digital) converters 38 and 39. A/D converters 38 and 39 convert the luminance signal Y_(A1) and color difference signal C_(A1) into 8-bit digital data “Y_(D1)” and “C_(D1)” based upon a sampling clock Ø_(S), for example of 13.5 MHz, output from a sampling clock generator 40.

Digital data Y_(D1), C_(D1), output from the A/D converters 38, 39, respectively, are supplied to a first digital signal processing circuit 41.

Under control of a memory-card-data transfer controlling section 42, the first digital signal processing circuit 41 performs a predetermined signal processing (e.g., control of the output timing, or adding the parity check code) required for storing the digital data Y_(D1), C_(D1) output from the respective A/D converters 38, 39 into an image memory 24a in the memory card 24. Processing circuit 41 also supplies the digital data Y_(D1), C_(D1) to the interface 43 in a predetermined order.

The memory-card-data transfer control section 42 performs its data transfer in synchronism with a signal produced based upon the control signal output from the control section 33, a clock Ø₁ input from the memory-card-data transfer clock generator 44 via AND gate 45 and OR gate 46, and a clock Ø₂ input from a control clock generator 47 via OR gate 46.

Then, the memory-card-data transfer control section 42 performs various control operations via the interface 43 to the image memory 24a and the addressing operation, and outputs a transfer completion signal to the control section 33 when the data transfer to the image memory 24a of memory card 24 is accomplished.

It should be noted that a clock Ø_(B) derived from the reference clock generator 49 is supplied to the sampling clock generator 40, and control clock generator 47.

Also, the sampling clock Ø_(S) is supplied to memory-card-data transfer clock generator 44, from the sampling clock generator 40. The sampling clock Ø_(S) and the transfer clock Ø₁ establish substantially the synchronism condition of the memory-card-data transfer clock generator 44.

A data output bus “C” of the interface 43 is connected to the frame memory 50. The frame memory 50 has a memory capacity sufficient for storing the digital data corresponding to one frame of image data. Frame memory 50 is addressed under the address control of a frame-memory-data transfer control section 51, and is furthermore read/write-controlled, and chip-enable-controlled, by control section 51. The digital data output from the frame memory 50 is supplied to a digital signal processing circuit 52 and to a digital image signal output terminal 19a.

The functions of the digital signal processing circuit 52 are to separate the digital data output from the frame memory 50 into luminance data Y_(D2) and color difference data C_(D2), and to output both the luminance data Y_(D2) and color difference data C_(D2) to D/A (digital-to-analog) converters 53 and 54 at a predetermined controlled timing. The overall operation of the digital signal processing circuit 52 is under control of the frame-memory-data transfer control section 51. When parity check data is added to the digital data derived from the A/D converters 38, 39 in the first digital signal processing circuit 41, the parity check operation will be executed in the second digital signal processing circuit 52.

The luminance data Y_(D2) and color difference data C_(D2) are converted into corresponding analog signals Y_(A2) and C_(A2) by the D/A converters 53 and 54, and thereafter these analog signals Y_(A2) and C_(A2) are output to the color encoder 55.

Color encoder 55 produces a NTSC (National Television Systems Committee) color television signal based upon a horizontal sync (synchronizing) signal H_(sync) and a vertical sync signal V_(sync) supplied from a video sync signal generator 56, and the above-described analog luminance signal Y_(A2) and analog color difference signal C_(A2), and then, outputs this NTSC color television signal to a liquid crystal television unit 23 and an analog image signal output terminal 19b, respectively.

CONTROL OPERATIONS OF CONTROL SECTION

As previously described, the control section 33 outputs the various control signals in accordance with the various conditions of the above-mentioned release switch 13, operation mode selecting switch 16 and output mode selecting switch 17.

First, a recording command signal “D” output from the control section 33 is supplied as an enable signal to the sampling clock generator 40, and also to the memory-card-data transfer control section 42 and to the AND gate 45. AND gate 45 outputs the transfer clock Ø₁ derived from the memory-card-data transfer clock generator 44 via an OR gate 46 to the memory-card-data transfer control section 42 based upon the output of the recording command signal D. The memory-card-data transfer control section 42 controls the first digital signal processing circuit 41 in response to the outputs of the recording command signal D and transfer clock Ø₁, and write-controls the digital data output from the first digital data signal processing circuit 41 into the image memory 24a of the memory card 24.

An erasing command signal “E” output from the control section 33 is supplied to the memory-card-data transfer control section 42 so as to erase the digital data stored in the image memory 24a under the control of the memory-card-data transfer control section 42. A reproducing command signal “F” derived from the control section 33 is supplied (i) via an OR gate 57 to a flip-flop 58, the frame-memory-data transfer control section 51, and an AND gate 59; and (ii) via an OR gate 60 to an AND gate 61.

The flip-flop 58 is reset in response to final address signal supplied from the frame-memory-data transfer control section 51 designating the final address of the frame memory 51. Flip-flop 58 transfers its set output “Q” to the frame-memory-data transfer control section 51, memory-card-data transfer control section 42, and to the AND gate 48, and also via an inverter 62 to the AND gate 59. The AND gate 48 sends via the OR gate 46 the control clock Ø₂ derived from the control clock generator 47 to the memory-card-data control section 42, and via an OR gate 63 to the frame-memory-data transfer control section 51 based upon the signal conditions given from the set output “Q” of the flip-flop 58. Both the memory-card-data transfer control section 42 and the frame memory-data transfer control 7section 51 control the data transfer from the image memory 24a to the frame memory 50 based upon the output signal of the OR gate 57, the set output Q of the flip-flop 58, and the control clock Ø₁ . The AND gate 59 supplies its gate output to the recorder control signal output terminal 19d and an AND gate 64 based upon the output signal of the OR gate 57 and the set output Q of the flip-flop 58 supplied via the inverter 62 thereto. The AND gate 64 transfers the control clock Ø₃ output from the control clock generator 47 to a transfer clock generator 65 and the video sync signal generator 56, respectively, in response to the output of the AND gate 59. Transfer clock generator 65 derives a transfer clock Ø₅ based upon the clock Ø₃, and supplies this transfer clock Ø₅ to the AND gate 61.

The AND gate 61 furnishes the transfer clock Ø₅ via the OR gate 63 to the frame-memory-data transfer control section 51 based upon the output of the OR gate 60. The function of the frame-memory-data transfer control section 51 is to transfer the image data previously stored in the frame memory 50 to the second digital signal processing circuit 52 based upon the outputs from the flip-flop 58 and the transfer clock Ø₅.

The video sync signal generator 56 produces the horizontal sync signal H_(sync) and vertical sync signal V_(sync) according to the NTSC television system in response to the control clock Ø₃. The horizontal sync signal H_(sync) is supplied to the color encoder 55. The vertical sync signal V_(sync) is similarly supplied to the color encoder 55, and to the sync signal output terminal 19c and to AND gate 66. The transfer command signal “G” output from the control section 33 is supplied to the other input terminal of the AND gate 66, the output of which is supplied to a counter 67.

The counter 67 counts the vertical sync signal V_(sync) which is supplied via the AND gate 66 thereto, and supplies a carry output “C” to the flip-flop 68 when the counting value of the counter 67 becomes a predetermined number. In other words, a predetermined number (for example, 10) of the vertical sync signal V_(sync) is input into the counter 67.

The flip-flop 68 supplies its set output “Q” via the OR gate 60 to the AND gate 61 and also to the AND gate 69. The AND gate 69 supplies a control clock Ø₄ derived from the control clock generator 47 to a time counter 70 in response to the set output Q of the flip-flop 68. The time counter 70 counts the time based upon the control clock Ø₄, and furnishes the carry output to a set terminal “S” of the flip-flop 71 when a predetermined time, e.g., 10 seconds has elapsed. The flip-flop 71 supplies its set output Q to an AND gate 72.

The AND gate 72 receives the final address signal derived from the frame-memory-data transfer control section 51 at its other input terminal, when transfer section 51 designates the final address of the frame memory 50. Then, the AND gate 72 supplies its output to the control section 33 as a transfer completion signal, and also to the reset terminals of the counter 67, flip-flops 68, 71 and time counter 70.

The transfer command signal “G” output from the control section 33 is supplied via the AND gate 66 and OR gate 57 to the flip-flop 58 and frame memory data transfer control section 51.

The control section 33 also supplies terminal control signals “H” and “I” to the digital image signal output terminal 19a and to the analog image signal output terminal 19b respectively in accordance with the switch conditions of the output mode selecting switch 17.

CIRCUIT ARRANGEMENT OF VIDEO TAPE RECORDER

Referring now to FIG. 4, a circuit arrangement of the video tape recorder 25 will be described.

For the sake of simplicity, only the circuit arrangement of the image signal processing system will be described and the remaining circuit arrangement will not be described.

The video tape recorder 25 includes a digital image signal input terminal 80a, an analog image signal input terminal 80b, a sync signal input terminal 80c and a remote control signal input terminal 80d.

The analog image signal input terminal 80b is connected to a color separating circuit 81. The function of the color separating circuit 81 is to separate a luminance signal Y_(A3), color difference signals (R-Y) and (B-Y), and a vertical sync signal V_(sync) from the NTSC signal input from the analog image signal input terminal 80b. These color difference signals (R-Y) and (B-Y) are supplied to the line sequential circuit 82.

The line sequential circuit 82 alternately selects the color difference signals (R-Y), (B-Y) derived from the color separating circuit 81 and sequentially outputs the selected color difference signal to an A/D converter 83.

The luminance signal Y_(A3) is, on the other hand, directly input into an A/D converter 84, which is output from the color separating circuit 81. The A/D converters 83 and 84 convert the luminance signal Y_(D3) and color difference signal C_(A3) into 8-bit digital data Y_(D3), C_(D3), respectively, in synchronism a sampling clock Ø_(S) output from a sampling clock generator 85. A/D converters 83, 84 output the digital data Y_(D3), C₃ into a first digital signal processing circuit 86.

The first digital signal processing circuit 86 performs a predetermined digital processing (for instance, the parity code being added) on the digital data Y_(D3), CD₃ supplied from the A/D converters 83, 84, and thereafter outputs the luminance data Y_(D3) and color difference data C_(P3) to a first recording signal converting circuit 88 via a gate circuit 87 in a predetermined order. 8-bit digital image data from the digital-image-signal input terminal 80a is supplied to the first recording signal converting circuit 88 via the gate circuit 89.

In the first recording signal converting circuit 88, the 8-bit digital data input thereto is separated into the upper 3-bit data, medium 3-bit data and lower 2-bit data, and thereafter, these pieces of separated digital data are modulated on the respective magnetic recording signals to output serial digital data. The magnetic recording signals output from the first recording signal converting circuit 88 are supplied via corresponding AND gates 90, 91 and 92 to respective magnetic recording heads 93, 94 and 95. That is, the upper 3-bit data is supplied to the magnetic recording head 93, the medium 3-bit data is supplied to the magnetic recording head 94, and the lower 2-bit data is supplied to the magnetic recording head 95 in serial data form.

The magnetic recording heads 93, 94, 95 are mounted on a rotary cylinder 96. The rotary cylinder 96 is rotated by a motor 97. A magnetic tape 36a to a magnetic cassette tape 26 is wound on the rotary cylinder 96. With the above-described construction, the magnetic recording heads 93 to 95 perform a helical scanning with respect to the magnetic tape 26a and accordingly the digital data are sequentially recorded on three tracks of the magnetic tape 26a in a single scanning.

The magnetic recording heads 93 to 95 furnish a readout signal from the magnetic tape 26a to a second recording signal converting circuit 101 via AND gates 98 to 100.

After the second recording signal converting circuit 101 demodulates the signals supplied from the magnetic recording heads 93 to 95, the demodulated signals are synthesized to obtain 8-bit digital data which is then sent to a second digital signal processing circuit 102.

The second digital signal processing circuit 102 performs a parity check on the 8-bit digital data derived from the second recording signal converting circuit 101, and separates the input 8-bit digital data into the luminance data Y_(D4) and color difference data C_(D4), and then outputs them to the D/A converters 103 and 104. A luminance signal Y_(D4) and a color difference signal C_(A4) which are converted by the D/A converters 103, 104, are supplied to a color encoder 105 outputs the NTSC color television signal to the NTSC signal output terminal 106.

As shown in FIG. 4, a control section 107 is employed in the video tape recorder. The control section 107 produces various control signals in response to an operation key 108 which is manually operated by a user, and in response to the remote control signal sent from the remote control signal input terminal 80d. First, a gate control signal H derived from the control section 107 is supplied directly to the gate circuit 87, and is supplied via inverter 109 to the gate circuit 89 so as to control gate circuits 87, 89. Secondly, a recording command signal “I” produced in the control section 107 is supplied to the AND gates 90 to 92 to control the supply of the output signals of the first recording signal converting circuit 88 to the corresponding magnetic recording heads 93 to 95. Also, reproducing command signal “J” sent from the control section 107 is supplied to the AND gates 98 to 100 to control the supply of the signals read out by these magnetic recording heads 93 to 95 to the second recording signal converting circuit 101. A motor control signal “K” from the control section 107 is supplied to a motor drive control section 110 for controlling the rotation of the motor 97.

Upon receipt of the motor control signal “K” and also the vertical sync signal V_(sync) supplied via an OR gate 111 from the color separating circuit 81 and sync signal input terminal 80c, the control section 107 controls the motor 97.

OVERALL OPERATION OF ELECTRONIC STILL CAMERA SYSTEM

Overall operation of the electronic still camera system will now be described in detail.

RECORDING IMAGE DATA IN MEMORY CARD

When a user wishes to take a picture, or image of an object and record it on the memory card 24 as the image data, the user first sets the operation mode selecting switch 16 to the “recording mode” camera apparatus 10 shown in FIG. 2. Then, the camera apparatus 10 is directed toward the object, and the release switch 13 is depressed about half way, so that the switch 13a is closed as illustrated in FIG. 3.

When the switch 13a is closed, the output signals from the sensor 32 are read out, and the focus sensing information, diaphragm open-angle information and shutter open-time information are calculated, and the resultant data are supplied to the optical processing control section 31 under the control of the control section 33.

The optical processing control section 31 controls the lens position, diaphragm open-angle and so on of the optical processing section 30 based on the various information supplied from the control section 33. Thereafter, when the user fully depresses the release switch 13 over its full travel path, the switch 13b is closed and the recording command signal “D” from the control section 33 is supplied to the sampling clock generator 40, to AND gate 45, and to memory-card-data transfer control section 42, respectively. Similarly, the shutter operation command is supplied to the optical processing control section 31. As a consequence, the shutter (not shown in detail) of the optical processing section 30 is actuated under control of the optical processing control section 31 so that the object image is focused onto the image sensing device 34. Moreover, the control section 33 outputs an operation command to the device drive section 35, and the electronic image signal which is produced in the image sensing device 34 by photoelectric-converting of the object's image, is supplied to the color separating circuit 36 in such a manner that the photoelectric-converted image data is sequentially supplied thereto one pixel of the image data at a time (i.e., pixel-by-pixel).

In the color separating circuit 36, the luminance signal Y_(A1), and color difference signals (R-Y), (B-Y) are produced from the electronic image signal derived from the image sensing device 34, and the luminance signal Y_(A1) is output to the A/D converter 38. The color difference signals (R-Y), (B-Y) are output to the line sequential processor 37.

On the other hand, in the line sequential processor 37, the color difference signals (R-Y), (B-Y) are alternatively selected for every one pixel and the selected color difference signals are sequentially supplied to the A/D converter 39.

From the A/D converters 38 and 39, the 8-bit luminance data Y_(D1) and the 8-hit color difference data C_(D1) are outputresponsive to the luminance signal Y_(A1) and color difference signal C_(A1), respectively, in synchronism with the sampling clock Ø_(S) derived from the sampling clock generator 40. Then, the luminance data Y_(D1) and color difference data C_(D1) are input into the first digital signal processing, circuit 41, and are thereafter stored into the image memory 24a or the memory card 24 under the control of the memory-card-data transfer control section 42. The memory-card-data transfer control section 42 receives the transfer clock Ø₁ from the memory-card-data transfer clock generator 44 via the AND gate 45 and OR gate 46, and controls the first digital signal processing circuit 41 and image memory 24a in response to the transfer clock Ø₁.

RECORDING FORMAT OF IMAGE MEMORY

The image data processed in the electronic still camera system are recorded on the image memory 24a in the recording formats as illustrated in FIGS. 5 and 6.

In the image memory 24a, as shown in FIG. 5, a 525-line address space is formed in the image data recording area of 1 frame in accordance with the scanning line number of the NTSC color television system. Therefore, the Image data consisting of 1720 bytes can be recorded on each memory line. Under the control of the memory-card-data transfer control section 42, the odd field image data is recorded on the memory area from a 1st line to 860 bytes of a 263rd line. whereas the even field image data is recorded on the memory area from 861 bytes of the 263rd line to the end of the 525th line. Similarly, the image data corresponding to the horizontal scanning is stored in each line memory area from a first byte to a 1690th-byte, and the image data of “0” corresponding to the horizontal retrace time, or flyback time, is recorded on the remaining 30 bytes of each recording line within the memory area defined by the 1st line to the 244th line, and the 861 bytes of the 263rd line to the 860 bytes of the 507th line, under the control of the memory-card-data transfer control section 42. In addition, the image data of “0” corresponding to the vertical retrace time, or flyback time, is recorded on the memory area defined by the 245th line to the 860 bytes of the 263rd line, and the 861 bytes of the 243rd line to the 525th line.

When the parity data is added to the digital image data in the first digital signal processing circuit 41, this parity data is stored in the “0” data recording area of the above-described image memory 24a.

The memory-card-data transfer control section 42 controls the first digital signal processing circuit 41 in such a manner that the recording formats for the respective lines of the image memory 24a become a recording format as shown in FIG. 6.

That is, under the control of the memory-card-data transfer control section 42, the luminance data Yn which has been sampled every pixel and A/D-converted, and the color difference data (R-Y)n and (B-Y)n which have been alternately selected to be A/D-converted, are sequentially recorded in the order of the color difference data and luminance data.

When the transfer operation of the 1-frame image data to the memory card 24 is completed under the control of the memory-card-data transfer control section 42, a transfer completion signal is output from the memory-card-data control section 42 to the control section 33. Under this condition, the control section 33 stops outputting of the recording command signal “D” and is brought into the waiting condition for the operation of the release switch 13.

IMAGE DATA REPRODUCTION

Reproducing the image data stored in the memory card 24 will now be described with reference to FIG. 3.

First, a user sets the operation mode selecting switch to the reproducing mode. In the reproducing mode, the control section 33 shown in FIG. 3 outputs the reproducing command signal “F”. This reproducing command signal “F” sets the flip-flop 58 via OR gate 57. In response to the set output from the flip-flop 58, the control clock Ø₂ is applied via the AND gate 48. OR gates 46 and 63 to the memory-card-data transfer control section 42 and frame-memory-data transfer control section 51.

In response to the reproducing command signal “F”, the image data is read out from the image memory 24a under the control of the memory-card-data transfer control section 42, and the image data transferred from the image memory 24a is written into the frame memory 50 under the control of the frame-memory-transfer control section 51.

It should be understood that the above-described frame memory 50 has a memory capacity capable of recording 1-frame image data, and also the same address space as that of the image memory 24a.

When the image data transfer operation from the image memory 24a to the frame memory 50 is completed, i.e., the final address of the frame memory 50 is designated in the frame-memory-data transfer control section 51, the final address signal is output from the frame-memory-data transfer control section 51, which resets flip-flop 58. Thereafter, the set output signal “Q” of the flip-flop 58 becomes “0” and no control clock Ø₂ is supplied to the frame-memory data transfer control section 51 and memory-card-data-transfer control section 42. The frame memory-data transfer control section 51 will commence the reading control of the image data to the frame memory 50.

Since the flip-flop 58 is reset, a “1” signal derived from the inverter 62 is supplied to AND gate 59, the reproducing command signal “F” is supplied to the AND gate 59 via OR gate 57, and the control clock Ø₃ is applied via the AND gate 64 to the transfer clock generator 65 and video sync signal generator 56. Thereafter, the transfer clock generator 65 sends the transfer clock Ø₅ via the AND gate 61 and OR gate 63 to the frame-memory-data transfer control section 51. Upon receipt of the transfer clock Ø₅, the frame-memory-data transfer control section 50 commences to control the image data transfer from the frame memory 51 to the second digital signal processing circuit 52.

The video sync signal generator 56 outputs the horizontal sync signal H_(sync) and vertical sync signal V_(sync) to the color encoder 55.

In the second digital signal processing circuit 52, the digital data transferred from the frame memory 50 is separated into the luminance data Y_(D2) and color difference data C_(D2) which are then transferred to the corresponding D/A converters 53 and 54. The luminance signal Y_(A1) and color difference signal C_(A2) derived from the respective D/A converters 53 and 54 are input into the color encoder 55. These signals are encoded into the desired NTSC color television signal in the color encoder 55, and the NTSC color television signal is supplied to both the liquid crystal television unit 23 and to the analog signal output terminal 19b.

In this case, when the output mode selecting switch 17 is set to the A-OUT (Analog-Output) mode, and an external monitor (not shown) is connected to the analog image signal output terminal 19b, the reproduced image data can be displayed on the external monitor.

IMAGE DATA TRANSFERRED TO VIDEO TAPE RECORDER

Referring back to FIGS. 3 and 4, a description will be given of transferring image data to the video tape recorder, which image data has been stored in the memory card 24.

First, a user confirms that the video tape recorder 25 is set to the digital recording mode, and then the output mode selecting switch 17 is set to the D-OUT (Digital Output) mode. Under this condition, the control section 33 of the camera apparatus 10 selects the digital image signal output terminal 19a. The user connects the digital-image-signal output terminal 19a of the camera apparatus 10 to the digital-image-signal input terminal 80a of the video tape recorder 25; the sync signal output terminal 19c to the sync signal input terminal 80c; and the video control signal output terminal 19d to the remote control signal input terminal 80d. Then, the user sets the video tape recorder 25 to the digital recording mode. Under these circumstances the control section 107 of the video tape recorder 25 selects the gate circuit 89 by signal “H”.

When the user sets the operation mode selecting switch 16 to the transfer mode and actuates the release Switch 13, the transfer control signal “G” is output from the control section 33 (see FIG. 7). Since the transfer command signal “G” is output, the flip-flop 58 is set and thus, the image data is transferred from the image memory 24a to the frame memory 50 in a similar manner to the data reproduction made. When the data transfer operation to the frame memory 50 is completed, the final address signal is output from the frame-memory-data control section 51, which causes the flip-flop 58 to be reset. Since the flip-flop 58 is reset, the frame-memory-data-control section 51 starts to control the image data reading operation of the frame memory 50, and the control clock Ø₃ is applied to the transfer clock generator 65 and video sync signal generator 56.

However, under the above-described condition, since no transfer clock Ø₅ is supplied from the transfer clock generator 65 to the frame-memory-data transfer control section 51, the frame-memory-data control section 51 does not commence the data reading control of the frame memory 50.

When on the other hand, a “1” signal is output from the AND gate 59 by resetting the flip-flop 58, it is supplied to the remote-control-signal input terminal 80d or the video tape recorder 25 (FIG. 4) via the recorder-control-signal output terminal 19d, (FIG. 3). Thus, the video tape recorder 25 is brought into the digital image recording condition in response to the signal-supplied from the remote-control-signal input terminal 80d, and the control section 107 outputs the motor drive command “K” to the motor drive control section 110.

The video sync signal generator 56 in the camera apparatus 10 supplies the vertical sync signal V_(sync) to the counter 67 via the AND gate 66, to which the transfer command signal “G” has been applied, and also sends the vertical sync signal V_(synv) to the sync signal input terminal 80c of the video tape recorder 25 via the sync signal output terminal 19c.

In the video tape recorder 25, the vertical sync signal V_(sync) input from the sync signal input terminal 80c is supplied to the motor drive control section 110. The motor drive control section 110 performs the synchronization among the vertical sync signal V_(sync) the rotation number of the rotary cylinder 96, and the positions of the magnetic recording heads 93 to 95.

In the camera apparatus 10, the vertical sync signal V_(sync) is counted by the counter 67 (FIG. 3). When the count value of the count 67 reaches 10, the carry output “C” derived from the counter 67 sets the flip-flop 68 (see FIG. 7). Since the flip-fop 68 is set, the set output from terminal Q of the flip-flop 68 is supplied via the OR gate 60 to the AND gate 61, and the transfer clock Ø₅ is supplied to the frame-memory-data transfer control section 51 via OR gate 63. Under these conditions, the frame-memory-data transfer control section 51 transfers the image data stored in the frame memory 50 to the digital image signal output terminal 19a.

As previously described, in the camera apparatus 10 according to the preferred embodiment, no data transfer operation is performed until 10 vertical sync pulses V_(sync) are output to the video tape recorder 25 after the video tape recorder 25 is set to the recording condition, so that the video tape recorder 25 can record the image data transferred thereto under perfect synchronization with the vertical sync signal V_(sync).

The image data transferred from the digital-image signal output terminal 19a is supplied via the digital image signal input terminal 80a and gate circuit 89 to the first recording signal converting circuit 88.

In the first according signal converting circuit 88, the above-described transferred data are converted into a predetermined format, and the resultant data are supplied to the corresponding magnetic recording heads 93 to 95 so as to record the image data on the magnetic tape 26a.

RECORDING FORMATS OF MAGNETIC TAPE

Referring now to FIGS. 8 to 10, the recording formats of the magnetic tape 26a will be described.

The magnetic recording heads 93 to 95 are helical-scanned over the magnetic tape 26a, and 1-frame image data is recorded on the magnetic tape 26a during one scanning operation with three tracks. No signal recorded portion is formed on the image-data recorded portion corresponding to the vertical retrace, or flyback time within 1 field. As illustrated in FIG. 9, no signal recorded portion is made on the image-data recorded portion corresponding to the horizontal retrace, or flyback time within 1 horizontal scanning. The data recording formats for the respective pixels are as follows. The luminance data Yn, and the color difference data (R-Y)n. (B-Y)n which are alternately supplied every pixel, are successively recorded in the order of the color difference data and luminance data. If a parity code is added to the above data, it is recorded on the no signal recorded portion.

While the digital image data are processed in the video tape recorder 25, the control clock Ø₄ is supplied via the AND gate 69 to the time counter 70 and the time counter 70 and the time counter 70 counts the time lapse in the camera apparatus 10. When the time counter 70 has counted 10 seconds, the carry output “C” thereof sets the flip-flop 71. In the frame-memory-data transfer control section 51, when the final address signal is output the frame-memory-data transfer completion signal is output from the AND gate 72, so that the image data transfer operation is completed.

Similarly, in the video tape recorder 25, the video control signal output from the AND gate 59 of the camera apparatus 10 becomes “0”, indicating that the recording operation by the video tape recorder 25 is completed.

As previously described above, in the electronic still camera system according to the preferred embodiment of the invention, the still image data can be stored in the memory card 24 and, furthermore, the image data stored in the memory card 24 can be transferred to the video tape recorder 25. As a result, a compact electronic still camera apparatus 10 can be realized, and the still images can be readily edited on the video tape recorder 25. Since the data transfer from the camera apparatus 10 to the video tape recorder 25 is performed within a predetermined time period, the image data can be displayed on the TV monitor when the image is reproduced by the video tape recorder 25.

It should be noted that when it is desired to transfer the analog image signal from the camera apparatus 10 to an analog video tape recorder (not shown), the user simply sets the output mode selection switch 17 to the A-OUT mode, so that the NTSC color television signal can be obtained from the analog image data output terminal 19b, which is similar to the reproduction operation.

SECOND EMBODIMENT OF ELECTRONIC STILL CAMERA APPARATUS

Referring now to FIG. 11, another embodiment of an electronic still camera apparatus according to the present invention will be described.

The circuit arrangement shown in FIG. 11 corresponds to the circuit arrangements shown in FIGS. 1 and 2, and is similar to the circuit arrangement illustrated in FIG. 3.

For the sake of simplicity, the same reference numerals shown in FIG. 3 will be employed for denoting the same circuit elements shown in FIG. 11.

In FIG. 11, an output signal derived from the image sensing device 34 is supplied to an A/D converter 201 via an amplifier 200. The device drive section 202 for driving the image sensing device 34 is substantially synchronized with the sampling or control clock generator 203 for producing the sampling clock pulse Ø₅₂ which is applied to the A/D converter 201 in response to a control clock Ø₆ output from a control clock generator 204. The A/D converter 201 converts the analog signal, which is output from the image sensing device 34 every one pixel, into 8-bit digital data.

The output from the A/D converter 201 is supplied via a memory card interface 43 to an image memory 205 contained in the memory card 24. The image memory 205 is employed so as to sequentially store the digital data corresponding to each pixel of the image sensing device 34. If the image sensing device 34 stores 380,000 pixels, for example, the required memory area for 1-frame image data is on the order of 3M bits (mega bits).

When digital data reduction is performed for the digital data output from the A/D converter 201, the memory capacity of the image memory 205 for 1-frame data is less than 3 M bits.

The digital data read/write operation to the image memory 205 is controlled under the memory-card-data transfer control section 206. The memory-card-data transfer control section 206 is operated in synchronism with the clocks Ø₂, Ø₆ applied via the OR gate 46 thereto. While writing the digital data into the image memory 205, the memory-card-data control section 206 is operated in synchronism with the clock Ø₆ which is applied from the control clock generator 204 via the AND gate 45 and OR gate 46 thereto.

The image data output from the image memory 205 via the memory card interface 43 is supplied to the frame memory 207. The frame memory 207 has the same address space as that of the image memory area for 1 frame of the image memory 205.

The image data output from the frame memory 207 is supplied to a D/A converter 208. An analog image signal output from the D/A converter 208 is separated into the luminance signal Y_(A1) and color difference signals (R-Y), (B-Y) in the color separating circuit (video signal processor) 36. The color separating signals (R-Y), (B-Y) are supplied to the line sequential circuit 37 so as to be line sequential-processed. The resultant color difference signal C_(A1) is suppliedto the A/D converter 39 and to color encoder 55. The color encoder 55 produces the NTSC color television signal based upon the color difference signal C_(A1), luminance signal Y_(A1), horizontal sync signal H_(sync) and vertical sync signal V_(sync). This NTSC color television signal is supplied to the liquid crystal television unit 23 and to the analog image-signal output terminal 19b.

Both the luminance signal Y_(A1) and color difference signal C_(A1) are supplied to the corresponding A/D converters 38 and 39, where they are converted into two sets of 8-bit digital data Y_(D1) and C_(D1). Both the 8-bit digital data Y_(D1), C_(D1) are supplied via the first digital data processing circuit 41 to the digital-image signal output terminal 19a.

RECORDING OPERATION OF SECOND EMBODIMENT

In the recording mode, when the release switch 13 is depressed over its full travel path the control section 33 outputs operation command signals to the optical process control section 31, device driver section 202, sampling clock generator 203 and memory-card-data transfer control section 206.

Under the control of the optical processing control section 31, the shutter provided within the optical process section 30 is opened and the object's image is focused onto the image sensing device 34.

The image sensing device 34 sequentially outputs the to electron charges stored therein every one pixel to the A/D converter 201 under the control of the device drive section 202. The A/D converter 201 converts the charge signals derived from the image sensing device 31 into the 8-bit digital data, and supplies the 8-bit digital data via the interface 43 to the image memory 205. The memory-card-data transfer control section 206 sequentially designates the addresses of the image memory 205, and the digital data output from the A/D converter 201 is stored in the image memory 205. When the data corresponding to 1-frame image data is stored in the image memory 205, the transfer completion signal is output to the control section 33 from the memory-card-data transfer control section 206, which completes the recording process of the digital image data.

REPRODUCING AND TRANSFER MODES

The reproduction mode and the data transfer mode to the video tape recorder, for the embodiment of FIG. 11, will now be described.

It should be understood that although both the reproduction mode and transfer mode are basically the same as those of the first preferred embodiment, a difference exists in the digital image signal production whereby the NTSC color television signal is obtained from the digital data previously stored in the frame memory 207. That is, since the digital data transferred from the image memory 205 to the frame memory 207 correspond to the digital data which are obtained in accordance with each 1 pixel of the image sensing device 34, the digital data are converted by the D/A converter 208 into the corresponding analog signals. Then, said analog signals are supplied to the video signal processor (color separating circuit) 36 where they are separated into the luminance signal Y_(A1) and color difference signals (R-Y), (B-Y). The color difference signals (R-Y), (B-Y) are transferred to the line sequential processor 37. The line-sequential-processed color difference signal C_(A1) is supplied to the A/D converter 39 and to the color encoder 55. In the color encoder 55, the NTSC color television signal is produced based upon the color difference signal C_(A1), luminance signal Y_(A1) horizontal sync signal H_(sync) signal H_(sync) and vertical sync signal V_(sync) which are input together with the color difference signal C_(A1). The resultant NTSC color television signal is output into the liquid crystal television unit 23 and the analog image signal output terminal 19b.

Both the luminance signal Y_(A1) and color difference signal C_(A1) are supplied to the corresponding A/D converters 38, 39 where they are converted into the 8-bit digital data based upon the sampling clock Ø_(S) (for instance, 13.5 MHz) output from the sampling clock generator 40. The resultant digital data are processed in the first digital processing circuit 41. The processed digital data are sequentially output to the digital-image-signal output terminal 19a.

As previously described in detail, according to the second preferred embodiment, the following various operations are the same as those of the first preferred embodiment. That is, the digital image data are transferred from the image memory 205 to the frame memory 207 and from the frame memory 207 either to the liquid crystal television unit 23, or to the video tape recorder 25, which are under control of the memory-card-data transfer control section 206 and of the frame-memory-data transfer control section 51. Also, the controlling operation from the camera apparatus 10 to the video tape recorder 25 is the same as that of the first preferred embodiment during the transfer mode.

In the first and second preferred embodiments, NTSC color television signals are produced. However, the present invention is not limited to NTSC color television signals. Other types of color television signals may by produced, for example, in accordance with the PAL (Phase Alternation Line) system or the SECAM (Sequential Colours A Memoire) system.

Although the time counter 70 in the first and second preferred embodiments performs a 10-second counting operation, the counting time thereof may be freely chosen by a user. 

What is claimed is:
 1. A video data recording system, comprising: a still camera including optical means for forming an optical image on a predetermined plane in a housing of said still camera, image data processing means for receiving said optical image as a still image and for producing electronic image data representative of said still image, and still image data storing means for storing a limited number of electronic image data each representing an independent still image supplied from said image data processing means; video data storage means provided outside of said housing of said still camera for storing a large number of electronic image data each representing an independent still image; and control means coupled to said still image data storing means provided in said still camera and to said video data storage means provided outside of said still camera, and including means for repeatedly transferring one of said limited number of electronic image data stored in said still image data storing means to said video data storage means for a predetermined time period, and means for causing said video data storage means to store said repeatedly transferred electronic image data, such that said repeatedly transferred electronic image data stored in said video data storage means is used for reproducing as a still image for the predetermined time period.
 2. The video data recording system according to claim 1, wherein said still image data storing means includes detachable memory means for storing a limited number of the electronic image data, said detachable memory means being mountable to the housing of the still camera so as to be electrically coupled to said control means and to said video data storage means.
 3. The video data recording system according to claim 2, wherein said detachable memory means includes a detachable semiconductor memory means.
 4. The video data recording system according to claim 1, wherein said video data storage means comprises a magnetic storage means.
 5. A video data recording system, comprising: housing means; optical means arranged at least partly in said housing means for forming an optical image on a predetermined plane in said housing means; image data processing means arranged in said housing means for receiving said optical image as a still image and for producing electronic image data representative of said still image; a detachable semiconductor memory card mounted to said housing means and electrically coupled to said image data processing means when mounted to said housing means for storing a limited plural number of independent electronic image data supplied from said image data processing means; output terminal means arranged on said housing means and coupled to said detachable semiconductor memory card for outputting said electronic image data derived from said detachable semiconductor memory card when said detachable memory card is mounted to said housing means; control means arranged in said housing means for controlling a writing operation and a reading operation of said electronic image data to and from said detachable semiconductor memory card; video data storage means provided outside of said housing means and coupled to said output terminal means, for storing a large number of independent image data representative of still images, said large number being substantially greater than said limited number; said control means including transferring means for repeatedly transferring to said output terminal means at least one of said electronic image data for a predetermined time period, each electronic image data being representative of the still image stored in said detachable semiconductor memory card; and said video data storage means including magnetic recording means for recording magnetically said repeatedly transferred electronic image data from said output terminal means and means for reproducing said same electronic image data of said same still image stored in said video data storage means as a still image for the predetermined time period.
 6. A video data recording system, comprising: still image data storing means for storing a limited number of digital image data each representing an independent still image; video data storage means for storing a large number of digital image data each representing an independent still image, said large number being substantially greater than said limited number and including magnetic recording means for recording magnetically said large number of digital image data; and control means coupled to said still image data storing means and to said video data storage means for repeatedly transferring digital image data stored in said still image data strong means to said video data storage means for a predetermined time period and for causing said video data storage means to store said transferred digital image data, such that said transferred digital image data stored in said video data storage means is used for reproducing as a still image for the predetermined time period; and wherein said still image data storing means includes a detachable semiconductor memory card or storing a limited plural number of the digital image data, said detachable semiconductor memory card being mountable to a housing of the video data recording system so as to be electrically coupled to said control means and to said video data storage means when said detachable semiconductor memory card is mounted to the housing.
 7. A video data recording system, comprising: still image data storing means for storing a limited number of digital image data each representing an independent still image; video data storage means for storing a large number of digital image data each representing an independent still image, said large number being substantially greater than said limited number, and including magnetic recording means for recording magnetically said large number of digital image data; and control means coupled to said still image data stoning means and to said video data storage means for repeatedly transferring at least one of said limited number of digital image data stored in said still image data storing means to said video data storage means for a predetermined time period, said control means including means for causing said video data storage means to store said transferred digital image data; and wherein said still image data storing means includes a detachable semiconductor memory card for storing a limited plural number of the digital image data, said detachable semiconductor memory card being mountable to a housing of the video data recording system so as to be electrically coupled to said control means and to said video data storage means when said detachable semiconductor memory card is mounted to the housing.
 8. A still camera capable of being coupled to a video data storage means provided outside of a housing of said still camera for storing a large number of electronic image data, each representing a still image, said still camera comprising: optical means for forming an optical image on a predetermined plane in the housing of said still camera; image data processing means for receiving said optical image as a still image and for producing electronic image data representative of said still image; still image data storing means for storing a limited number of electronic image data each representing an independent still image supplied from said image data processing means; and control means coupled to said still image data storing means and to said video data storage means, and including means for repeatedly transferring one of said limited number of electronic image data stored in said still image data storing means to said video data storage means for a time period to store said repeatedly transferred electronic image data, such that said repeatedly transferred electronic image data stored in said video data storage means is used for reproducing as a still image for said time period.
 9. The still camera according to claim 8, wherein said still image data storing means includes detachable memory means for storing a limited number of the electronic image data, said detachable memory means being mountable to the housing of the still camera so as to be electrically coupled to said control means and to said video data storage means when said detachable memory means is mounted to said housing.
 10. The still camera according to claim 9, wherein said detachable memory means includes a detachable semiconductor memory means.
 11. A still camera capable of being coupled to a video data storage means provided outside of a housing of said still camera including magnetic recording means for recording magnetically a large number of electronic image data, each representing a still image, said still camera comprising: optical means for forming an optical image on a predetermined plane in the housing of said still camera; image data processing means for receiving said optical image as a still image and for producing electronic image data representative of said still image; a detachable semiconductor memory card mounted to said housing and electronically coupled to said image data processing means when mounted to said housing means, for storing a limited plural number of electronic image data each representing an independent still image supplied from said image data processing means, said large number being substantially greater than said limited number; and control means coupled to said detachable semiconductor memory card and to said video data storage means, and including means for repeatedly transferring for a predetermined time period one of said limited number of electronic image data stored in said detachable semiconductor memory card to said video data storage means to store said transferred electronic image data, such that said repeatedly transferred electronic image data stored in said video data storage means is used for reproducing as a still image for the predetermined time period.
 12. A still camera capable of being coupled to a video data storage means provided outside of a housing of said still camera for storing a large number of electronic image data, each representing a still image, said still camera comprising: housing means; optical means arranged at least partly in said housing means for forming an optical image on a predetermined plane in said housing means; image data processing means arranged in said housing for receiving said optical image as a still image and for producing electronic image data representative of said still image; a detachable semiconductor memory card mounted to said housing and electrically coupled to said image data processing means when mounted to said housing, for storing a limited plural number of independent electronic image data supplied from said image data processing means, said large number being substantially greater than said limited number; output terminal means arranged on said housing means and coupled to said detachable semiconductor memory card for outputting said electronic image data derived from said detachable semiconductor memory card when said detachable semiconductor memory card is mounted to said housing; and control means arranged in said housing for controlling a writing operation and a reading operation of said electronic image data to and from said detachable semiconductor memory card, and including transferring means for repeatedly transferring for a predetermined time period to said output terminal means at least one of said electronic image data each being representative of the still image stored in said detachable semiconductor memory card; and wherein said video data storage means includes magnetic recording means for magnetically storing said repeatedly transferred electronic image data from said output terminal means, and means for reproducing said electronic image data as a still image for the predetermined time period.
 13. A digital still camera comprising: a housing; an optical image sensor incorporated in said housing and having a predetermined plane, for forming, on the predetermined plane, an optical image as a still picture of an object; an image data processor incorporated in said housing for forming digital image data corresponding to the optical image formed on the predetermined plane of said optical image sensor; a first memory incorporated in said housing and coupled to said image data processor, for storing a plurality of digital image data formed by said image data processor; a second memory incorporated in said housing and coupled to said first memory, for storing one of the plurality of digital image data stored in said first memory; a digital-to-analog converter incorporated in said housing and coupled to said second memory, for converting the digital image data stored in said second memory to analog image data; a liquid crystal display mounted on said housing and coupled to said digital-to-analog converter, for receiving the analog image data converted by said digital-to-analog converter to display a still picture of the object; a digital output terminal coupled to said second memory, adapted for outputting the digital image data stored in said second memory; an analog output terminal coupled to said digital-to-analog converter, adapted for outputting the analog image signal converted by said digital-to-analog converter; and a switch coupled to both said digital output terminal and said analog output terminal, for selecting one of said digital output terminal and said analog output terminal, allowing the selected terminal to output image data.
 14. A digital still camera comprising: housing means; optical image sensing means incorporated in said housing means and having a predetermined plane, for forming, on the predetermined plane, an optical image as a still picture of an object; image data processing means incorporated in said housing for forming digital image data corresponding to the optical image formed on the predetermined plane of said optical image sensor; first storing means incorporated in said housing means and coupled to said image data processing means, for storing a plurality of digital image data formed by said image data processing means; second storing means incorporated in said housing means and coupled to said first storing means, for storing one of the plurality of digital image data stored in said first storing means; digital-to-analog converting means incorporated in said housing and coupled to said second storing means, for converting the digital image data stored in said second storing means to analog image data; liquid crystal displaying means mounted on said housing means and coupled to said digital-to-analog converting means, for receiving the analog image data converted by said digital-to-analog converting means to display a still picture of the object; digital output terminal means coupled to said second memory, adapted for outputting the digital image data stored in said second storing means; analog output terminal means coupled to said digital-to-analog converting means, adapted for outputting the analog image signal converted by said digital-to-analog converting means; and switching means coupled to both said digital output terminal means and said analog output terminal means, for selecting one of said digital output terminal means and said analog output terminal means, allowing the selected terminal means to output image data. 